Product Overview: SN74ACT533NSRG4

The SN74ACT533NSRG4 is a high-performance, octal D-type transparent latch with 3-state outputs, designed and manufactured by Texas Instruments. This integrated circuit is part of the SN74 series, which is renowned for its reliability and versatility in a wide range of digital applications.

Key Features

• Logic Type: Octal D-Type Transparent Latch
• Output Type: 3-State
• Operating Voltage: 4.5V to 5.5V
• IC Interface Type: Parallel
• Propagation Delay Time: 9ns at 5V
• Operating Temperature: -40°C to +85°C
• Package / Case: 20-SOIC
• Mounting Type: Surface Mount
• RoHS: Compliant

Performance and Quality

The SN74ACT533NSRG4 is engineered for optimal speed performance and minimal propagation delay, making it suitable for high-speed memory buffering and data storage applications. With its wide operating voltage range and fast setup and hold times, this device can seamlessly integrate into various digital systems. Texas Instruments ensures high-quality standards, and the SN74ACT533NSRG4 is no exception, offering excellent performance consistency and robustness in challenging environments.

Applications

This versatile latch is commonly used in data storage, memory buffering, and data manipulation tasks. It is ideal for applications that require the temporary storage of data and the ability to control the flow of data to downstream components. The 3-state outputs allow for connection to a bus-oriented system without the risk of bus contention.

Environmental and Regulatory Compliance

As an environmentally conscious product, the SN74ACT533NSRG4 complies with RoHS standards, ensuring that it is free from hazardous substances commonly found in electronic components. This commitment to environmental sustainability makes it a suitable choice for eco-friendly projects and applications.

Whether used in complex computing systems, industrial control panels, or consumer electronics, the SN74ACT533NSRG4 from Texas Instruments delivers the reliability and performance that modern digital applications demand.